DE10351579A1 - Method for checking weld seams during a welding process and an apparatus for carrying out this method - Google Patents

Abstract

According to the invention, the problems outlined are solved by a method in which a part of the radiation intensity generated by the arc is detected by a photosensitive detector after passing through an intensity reducer and the signal of the detector is processed mathematically by a digital computer unit and from this a digital pattern is generated, which is compared with a stored in the memory reference pattern and a deviation is signaled by a signal generator.

Description

object The invention is a method having the features of the claim 1 and a device with the features of claim 4 for carrying out this Procedure, for the detection and reporting of faulty welds during the welding a welding machine.

In the automotive industry, but also in the production of steel pipes, Containers and components are often replaced by components and components Arc welding by means of welding machines connected with each other. In doing so, the weld will be affected by the extreme heat one between an electrode and the seam between them Components generated electric arc generated. The arc lets the adjacent surfaces of the individual components melt together.

Point however, for example, the components to be curved curved shapes On, it comes again and again to incorrect positioning of these components at the assembly the welding machine, what a deviation of the weld from Target course has the consequence. Often Then it comes to an interruption and thus to a faulty Shit seam.

But also intensity fluctuations of the electric arc - the caused by variation of the distance between electrode and material can be - and demolition of the electrode material a thermal damage to be welded Materials or incomplete welds for Episode.

It is therefore necessary, the production problems occurring during arc welding through an appropriate monitoring system to control that completely all welds detected. At present, especially in the automotive industry, the test mostly over a (faulty) visual and thus cost-intensive - because personnel-intensive - control following the welding process.

Out that's why it is advantageous to have a method that welds during the welding the welding machine checked and in the case of a faulty weld made a message.

For this In the prior art, no patents are called, the one Detection and reporting of faulty welds during the welding process a welding machine describe.

Only in the testing of longitudinally welded pipes are devices based on ultrasonic measurements used instead of visual control, such as in DE 101 34 696 C1 explained. However, in this method, the test is possible only after completion of the welding process, but this is associated with an additional process step and thus with a financial overhead.

outgoing It is therefore the task of this prior art to provide a method and a device for detecting and reporting faulty Welds during the Welding process one welding machines to accomplish.

The procedural solution carried by the characterizing features of claim 1, advantageous Procedures emerge from the subclaims 2 and 3.

A Device according to said The object is achieved by the characterizing features of claim 4 solved. Advantageous embodiments Such a device are characterized in claims 5 to 16.

applications Such a device can be found according to claim 17.

The intensity and characteristics of the radiation 1 of the arc occurring in a welding process 2 between robotic arm 3 and the component to be welded 4 Depends on both the arc and the surface (shape) of the component.

Tear, for example, by missing electrode material of the arc 2 short-term, no radiation intensity is perceptible until the reconstruction of the arc. Increases the intensity of the arc 2 - For example, by reducing the distance between the component and the electrode - the intensity of the radiation increases sharply. But also the form 4.1 . 4.2 and 4.3 and the spatial orientation of the components to be welded affect the spatial distribution of the intensity of the radiation 1.1 . 1.2 and 1.3 , The shape and / or position changes - for example due to incorrect positioning in the holding device 5 - The components during the welding process, also changes the intensity distribution of the radiation.

According to the invention, the intensity of the radiation during the welding process by means of egg directly at the robot arm 3 attached sensor 6 and compared with a (previously recorded, typical for the process to be controlled) reference intensity profile in the current process. In the event of a deviation from the reference profile, a message will be issued so that the component, which may be provided with a faulty weld, can be discarded. In this case, the intensity and the spectral range of the radiation which is detected by the sensor can be adapted to the respective process by means of suitable components. In addition, several intensity profiles can be recorded simultaneously with one sensor and compared with the stored reference intensity profiles.

Based the drawings and the subsequent embodiments is the inventive method and the device for its implementation described in more detail.

Based the attached Drawings are preferred embodiments of the method according to the invention and devices for its implementation described in detail.

there is:

1 Schematic representation of a welding machine with a sensor mounted on the robot arm.

2 Schematic representation of the spatial intensity distribution of the radiation as a function of the shape and position of the components to be welded.

3 Scheme of the method for detecting and reporting defective welds during a welding operation.

4 Scheme of the advanced method for detecting and reporting faulty welds during a welding operation.

5 Scheme of the preferred method for detecting and reporting faulty welds during a welding operation.

6 Schematic representation of a device

7 and 8th alternative designs for devices.

1 shows a schematic representation of a process monitoring welding machine, which essentially consists of a robot arm 3 , a component to be welded 4 , a holding device 5 and a sensor 6 consists. In addition, the spatial intensity distribution of the radiation 1 , the arc of light 2 and the weld 7 shown.

2 shows possible manifestations of the spatial intensity distribution 1.1 . 1.2 and 1.3 the radiation depending on the shape and position (also depending on the holding device 5 ) of the components to be welded 4.1 . 4.2 and 4.3 and the location of the weld 7.1 . 7.2 and 7.3 ,

3 shows the procedure for the detection and reporting of faulty welds during a welding process. It hit parts of the radiation intensity 1 generated by the arc after passing through an intensity reducer 6.1 on a photosensitive detector 6.2 , The electrical signal of the detector is sent to a computer unit 6.3 passed. This computer unit mathematically processes the signal and generates a digital pattern. Subsequently, this pattern is compared with an existing pattern typical for the process step and stored in the data memory. In the case of a non-conformity of the currently recorded and the stored pattern, a signal is transmitted directly to the process control and / or to an optical and / or acoustic message unit 6.4 ,

in the Trap that recorded a new process step and in the data store is to be stored, the radiation intensity and thus the signal, as described above, stored as a "reference pattern" in the data memory.

4 shows an advanced approach. In this case, parts of the frequency spectrum of the radiation by an exclusion process 6.5 before hitting the photosensitive detector 6.2 hidden.

5 shows a preferred procedure. Here, different proportions of the radiation intensity meet 1 on several (at least two) spatially separated photosensitive detectors 6.2 whose signals are the computer unit 6.3 detected at the same time and, depending on the number of detectors, generates digital patterns.

6 shows a schematic representation of a device, as it can be used for detecting and reporting of defective welds during a welding operation. The device comprises a cleaning device 6.6 (For example, a windshield wiper and / or an air nozzle) directly on an optically transparent protective device 6.7 (eg a heat-resistant plastic or a glass) is attached. This protective device is intended to - possible - during the welding process - welding beads from fotoempfind keep the detector away. In order to detect the largest possible beam cross-section and thus to minimize interference that can be caused by contaminants on the protective device, behind the guard is an imaging system 6.8 (eg, one or more optical lenses). This is followed by an intensity reducer 6.1 , (eg, an optical shutter or a neutral filter) and a photosensitive detector 6.2 (eg a photodiode). The electrical signal of the detector is sent to a subsequent computer unit 6.3 passed. This computer unit consists of a signal converter (eg A / D converter) and a computer (eg processor), which processes the converted signal mathematically (eg digital filtering) and generates a digital pattern, which with which is stored in the data memory is compared. The output signal of the computer is passed on directly to the process control and / or serves for the direct control of a signal generator 6.4 (eg a flashing light or horn).

7 shows a design of the device similar 6 in which, however, between the intensity reducer 6.1 and the photosensitive detector 6.2 an exclusion element 6.5 (eg an optical frequency filter).

8th shows a design of the device similar 7 , but behind the intensity reducer 6.1 several (at least two) photosensitive detectors 6.2 whose signals are sent simultaneously to a subsequent computer unit 6.3 be passed on.

Claims (17)

Method for detecting and reporting defective weld seams during the welding process of an automatic welding machine, characterized in that a part of the radiation intensity ( 1 ), the arc ( 2 ) after passing through an intensity reducer ( 6.1 ) from a photosensitive detector ( 6.2 ) and the signal of the detector from a digital computer unit ( 6.3 ) is mathematically processed and from this a digital pattern is generated which is compared with a reference pattern stored in the memory and a deviation via a signal generator ( 6.4 ) is reported. Method according to Claim 1, characterized in that the frequency spectrum of the detected radiation is determined by an exclusion method ( 6.5 ) is limited. Method according to claim 1 or 2, characterized in that different proportions of the radiation intensity ( 1 ) on a plurality of spatially separated photosensitive detectors ( 6.2 ), and their signals from the computer unit ( 6.3 ) are recorded at the same time. Device for carrying out the method according to one of claims 1 to 3 for the detection and reporting of defective welds during the welding process of a welding machine, comprising a cleaning device ( 6.6 ), an optically transparent protective device ( 6.7 ), an imaging system ( 6.8 ), an intensity reducer ( 6.1 ), a photosensitive detector ( 6.2 ), a computer unit ( 6.3 ) and a signal generator ( 6.4 ). Apparatus according to claim 4, characterized in that the cleaning device ( 6.6 ) consists of a windscreen wiper, an air nozzle or a brush. Apparatus according to claim 4, characterized in that the protective device ( 6.7 ) consists of a heat-resistant plastic, a glass or a heat-resistant network. Device according to claim 4, characterized in that the imaging system ( 6.8 ) consists of one or more lenses. Apparatus according to claim 4, characterized in that the intensity reducer ( 6.1 ) consists of an optical shutter, a neutral filter or a gray filter. Device according to Claim 4, characterized in that the photosensitive detector ( 6.2 ) consists of a photodiode, a photoresistor, a photocell, a photomultiplier or a diode array. Apparatus according to claim 4, characterized in that the computer unit ( 6.3 ) consists of an A / D converter, as well as a processor, a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit) or an FPGA (Field Programmable Gate Array). Device according to claim 4, characterized in that the signal generator ( 6.4 ) consists of a flashing light, a horn or a vibration alarm. Apparatus according to claim 4, characterized in that the signal of the computer unit ( 6.3 ) is passed on directly to the process control. Apparatus according to claim 4, characterized in that between the intensity reducer ( 6.1 ) and the photosensitive detector ( 6.2 ) an exclusion element ( 6.5 ) is located. Device according to claim 13, characterized in that the exclusion element ( 6.5 ) consists of an optical frequency filter or a filter array. Apparatus according to claim 4, characterized in that behind the intensity reducer ( 6.1 ) several photosensitive detectors ( 6.2 ), the signals from the computer unit ( 6.3 ) are recorded at the same time. Apparatus according to claim 15, characterized in that in front of the photosensitive detectors ( 6.2 ) identical or different exclusion elements ( 6.5 ) are located. Device according to Claims 4 to 16, characterized that it finds use on a welding machine.